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Oct 24, 2016 - Enzyme promiscuity, which can be more precisely described as substrate permissiveness, mechanistic elasticity, and concomitant product ...
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Dynamic conformational states dictate selectivity toward native substrate in a substrate-permissive acyltransferase Olesya Levsh, Ying-Chih Chiang, Chun Fai Tung, Joseph P. Noel, Yi Wang, and Jing-Ke Weng Biochemistry, Just Accepted Manuscript • DOI: 10.1021/acs.biochem.6b00887 • Publication Date (Web): 24 Oct 2016 Downloaded from http://pubs.acs.org on October 27, 2016

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Dynamic conformational states dictate selectivity toward native substrate in a substrate-permissive acyltransferase Olesya Levsh,1,2 Ying-Chih Chiang,3 Chun Fai Tung,3 Joseph P. Noel,4 Yi Wang,3,* and Jing-Ke Weng1,2,* 1

Whitehead Institute for Biomedical Research, 9 Cambridge Center, Cambridge, MA 02142

2

Department of Biology, Massachusetts Institute of Technology, Cambridge, MA 02139

3

Department of Physics, The Chinese University of Hong Kong, Shatin, Hong Kong

4

Howard Hughes Medical Institute, Jack H. Skirball Center for Chemical Biology & Proteomics,

The Salk Institute for Biological Studies, La Jolla, CA *

To whom correspondence should be addressed. E-mail: [email protected] and [email protected]

ABBREVIATIONS HCT, hydroxycinnamoyl CoA: shikimate hydroxycinnamoyl transferase; RAS, rosmarinic acid synthase; MD, molecular dynamics; ORF, open reading frame; SAD, single-wavelength anomalous diffraction; LC-MS, liquid chromatography-mass spectrometry; MSA, multiple sequence alignment; RMSD, root-mean-square deviations KEYWORDS enzyme promiscuity, enzyme dynamics, phenylpropanoid metabolism, BAHD acyltransferase, HCT, catalytic mechanism

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ABSTRACT

Hydroxycinnamoyl CoA: shikimate hydroxycinnamoyl transferase (HCT) is an essential acyltransferase that mediates flux through plant phenylpropanoid metabolism by catalyzing a reaction between p-coumaroyl CoA and shikimate, yet it also exhibits broad substrate permissiveness in vitro. How do enzymes like HCT avoid functional derailment by cellular metabolites that qualify as non-native substrates? Here, we combine X-ray crystallography and molecular dynamics to reveal distinct dynamic modes of HCT under native versus non-native catalysis. We find that essential electrostatic and hydrogen-bonding interactions between the ligand and active site residues, enabled by active site plasticity, are elicited more effectively by shikimate than by other non-native substrates. This work provides a structural basis for how dynamic conformational states of HCT favor native over non-native catalysis by reducing the number of futile encounters between the enzyme and shikimate.

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Enzyme promiscuity, which can be more precisely described as substrate permissiveness, mechanistic elasticity, and concomitant product diversity, has long been regarded as a facilitator in the evolution of novelty1. In 1976, Jensen first theorized that primordial enzymes were generalists capable of multiple catalytic tasks and later evolved into more specialized catalysts2. Since then, the theory of enzyme recruitment, which posits that enzyme promiscuity provides a starting point for positive selection and leads to neofunctionalization via cycles of duplication and selection, has garnered experimental support3, 4. Generally, mutations that are neutral or nearly neutral to the primary function of the ancestral enzyme may alter its non-native functions, rendering new “raw materials” for selection to act upon, as long as they are not selected against5, 6

. Furthermore, the catalytic properties of discrete enzymes are subjected to selection in the

context of an in vivo metabolic system to maximize organismal fitness – catalytic machinery must be efficient enough to produce essential molecules when they are necessary, but not so efficient that it drains vital metabolite pools. As a result, natural enzymes – even those from the same enzyme family – exhibit kinetic parameters (e.g. Km and kcat determined against native substrates) that can span orders of magnitude but in general agree with the measured metabolite pools and fluxes in vivo7, 8. Previous studies also showed that catalytic specificity and efficiency of many natural enzymes could be further improved through directed evolution9-11. Together, these observations suggest that systems-level constraints imposed on natural enzymes might have prevented them from evolving toward the highest specificity and efficiency limits set by physicochemical and thermodynamic constraints, thereby setting the stage for substrate permissiveness. However, it remains largely unknown how enzymes with relaxed substrate specificity maintain their primary catalytic functions in the face of competing non-native substrates widely present in vivo.

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Plant specialized metabolism represents a rich network of rapidly evolving metabolic enzymes. Evolutionary exploitation of ancestral enzyme promiscuity has allowed new metabolic traits to emerge in diverse taxa of the plant kingdom12. The BAHD family of acyltransferases, named after the first four enzymes discovered from this family (BEAT, AHCT, HCBT, and DAT), are an important family of plant specialized enzymes responsible for the biosynthesis of a huge diversity of ester- and amide-containing natural products13. The BAHD family has radiated extensively throughout land plant evolution, with a small number of BAHD genes contained in the basal bryophytes, and the majority of BAHD homologs arising independently within major lineages of vascular plants14, 15. Members of the BAHD acyltransferase family can be identified by sequence homology and the universally conserved HXXXD and DFGWG motifs, although the biochemical functions of individual BAHD acyltransferases remain largely uncharacterized16. Hydroxycinnamoyl CoA: shikimate hydroxycinnamoyl transferase (HCT) is one of the few BAHD acyltransferases that exhibits an orthologous phylogenetic pattern across all land plants (Supplementary Figure S1)13. HCT transfers the p-coumaroyl group from the acyl donor p-coumaroyl CoA onto the 5-hydroxyl of the acyl acceptor shikimate to produce pcoumaroylshikimate, which in turn serves as a key intermediate for the first aromatic ring metahydroxylation step in the plant phenylpropanoid metabolism17. Important phenylpropanoids downstream of HCT include monolignols, building blocks of the polymer lignin in vascular plants, as well as a plethora of pigments, flavor compounds, UV protectants, and phytoalexins18. Since shikimate is a precursor for the biosynthesis of aromatic amino acids in plants, it has also been proposed that the involvement of HCT in phenylpropanoid metabolism implements a metabolic flux control in the pathway that is responsive to the availability of cytosolic shikimate19.

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Despite its essential role in plant phenylpropanoid metabolism, HCT displays inferior kinetic parameters. Previous studies reported a Km of 323 µM measured using Coleus blumei HCT (CbHCT) against its native acyl acceptor shikimate, a value one or two orders of magnitude greater than that of some of the other BAHD acyltransferases characterized previously20-23. Moreover, CbHCT can utilize a diverse array of non-native acyl donor and acceptor substrates to produce a variety of esters and amides in vitro24. Generally, substrate-permissive enzymes have been considered to be more evolvable than highly specific enzymes5, 25. Indeed, rosmarinic acid synthase (RAS), a BAHD associated with the Lamiaceae family, has apparently neofunctionalized from HCT after an ancestral gene duplication event24,

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(Supplementary

Figure S1). Rather than using shikimate as in HCT, RAS utilizes an alternative acyl acceptor, 4hydroxyphenyllactate, and produces p-coumaroyl-4′-hydroxyphenyllactate, a key precursor for the specialized rosmarinic acid biosynthesis26. We were intrigued by the fact that HCT, as an essential enzyme in plant phenylpropanoid metabolism, exhibits low substrate specificity. How does HCT maintain its specific metabolic function in vivo in the presence of other reactive metabolites that are able to access its active site and derail native catalysis? By combining approaches such as structural biology, site-directed mutagenesis, enzyme kinetics, and molecular dynamics (MD) simulation, we sought to gain a deeper understanding of the molecular interactions between HCT and its native substrate in addition to a range of non-native substrates. Based on our findings, we propose a model where specific conformational substates of the enzyme support efficient shikimate turnover but do not facilitate productive catalytic encounters with a range of non-native substrates.

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EXPERIMENTAL PROCEDURES Cloning and Site-directed Mutagenesis of HCTs The open reading frame (ORF) of AtHCT was PCR amplified from Arabidopsis cDNA, digested with Nco I and Xho I, and ligated into Nco I and Xho I-digested pHIS8-3 E. coli expression vector. The ORF of CbHCT (GenBank accession version CBI83579.1) was codon optimized for expression in E. coli, and synthesized as a gBlocks® Gene Fragment (Supplementary Data S2). The fragment was cloned into Nco I-digested pHIS8-4 E. coli expression vector using Gibson Assembly. Site-directed mutagenesis was performed according to the QuikChange II Site-Directed Mutagenesis protocol (Agilent Technologies).

Recombinant Protein Expression and Purification Protein expression constructs were transformed into E. coli BL21(DE3) strain and purified with affinity followed by size-exclusion chromatography, as previously described27. Detailed procedures of the protein purification protocol are provided in the Supplementary Experimental Procedures.

Protein Crystallization AtHCT crystals were grown by hanging drop vapor diffusion at 4 °C by mixing 2 µL 10 mg/mL protein with 1 µL of a reservoir solution containing 0.5 M ammonium acetate, 0.1M MOPSO-NaOH, pH 7.24, 18% PEG 8000. CbHCT crystals were grown by hanging drop vapor diffusion at 4 °C by mixing 1 µL 15 mg/mL protein with 1 µL of a reservoir solution containing 0.1 M Bis-Tris:HCl, 25% PEG 3350, pH 7.5. For soaking AtHCT crystals, soaking drops were prepared by mixing 1.8 µL of reservoir solution with either 0.2 µL of 100 mM p-coumaroyl CoA

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in water or 0.2 µL of 100 mM p-coumaroylshikimate in DMSO. For soaking CbHCT crystals, a soaking drop was prepared from 1.6 µL of reservoir solution mixed with 0.2 µL of 500 mM 3hydroxyacetophenone in DMSO, and 0.2 µL of 100 mM p-coumaroyl CoA in water. Crystals were transferred into soaking solution and incubated for 1 hour before transfer to a cryoprotection solution of 17% glycerol and reservoir solution. Apo crystals were cryoprotected without being soaked. Single crystals were mounted in a cryoloop and flash frozen in liquid nitrogen.

X-ray Diffraction and Structure Determination X-ray diffraction data was collected at beamlines 8.2.1 and 8.2.2 of the Advanced Light Source at Lawrence Berkeley National Laboratory on ADSC Quantum 315 CCD detectors for AtHCT crystals, and at beamline 24-ID-E of the Advanced Photon Source at Argonne National Laboratory on a CCD-based ADSC Quantum 315 detector for CbHCT crystals. Diffraction intensities were indexed and integrated with iMosflm28, and scaled with Scala under CCP429, 30. The phase of the AtHCT SeMet apo structure was determined by single-wavelength anomalous diffraction (SAD). The phases for the other HCT structures were determined with molecular replacement using Phaser under Phenix31. Further structural refinement utilized Phenix programs31. Coot was used for manual map inspection and model rebuilding32. Crystallographic calculations were performed using Phenix. The Protein Data Bank accession numbers for the apo-, p-coumaroyl CoA-bound, and p-coumaroyl shikimate-bound AtHCT, and the apo- and 3hydroxyacetophenone-bound CbHCT are 5KJS, 5KJT, 5KJU, 5KJV, and 5KJW, respectively.

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Comparative Sequence and Structure Analysis AtHCT, CbHCT, SbHCT, SmHCT, PpHCT, and CbRAS protein sequences were derived from NCBI33. The PaHCT sequence was derived from ConGenIE34. The remaining sequences were derived from 1KP35. In all cases, AtHCT was used as the search query. Amino acid alignment of HCT orthologs was created using T-COFFEE with default settings36. ESPript 3.037 was used to display the multiple sequence alignments as shown in Figure 2F and Supplementary Data S1. Atomic coordinates of apo (PDB ID: 4KE4) and p-coumaroylshikimate and CoA-bound (PDB ID: 4KEC) SbHCT were retrieved from the Protein Data Bank38. All structures were aligned based on topology with the SSM superpose function in Coot32, 39. KVFinder40 was used to calculate enzyme active site volumes (additional details can be found in Supplementary Experimental Procedures). All structural figures were created with the PyMOL Molecular Graphics System, version 1.3 (Schrödinger, LLC)41.

Phylogenetic analysis Evolutionary analyses were conducted in MEGA742. A multiple sequence alignment was built using MUSCLE with the UPGMB clustering method. The analysis involved 38 amino acid sequences. All positions with less than 95% site coverage were eliminated. There were a total of 421 residue positions in the final dataset. Eight iterations were performed with a gap open penalty of -2.9 and a gap extend penalty of 043. The phylogenetic tree was inferred by using the Maximum Likelihood method based on the Le_Gascuel_2008 model44. The tree with the highest log likelihood (-12321.8762) is shown. Initial tree(s) for the heuristic search were obtained automatically by applying Neighbor-Join and BioNJ algorithms to a matrix of pairwise distances estimated using a JTT model, and then selecting the topology with superior log likelihood value.

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A discrete Gamma distribution was used to model evolutionary rate differences among sites [5 categories (+G, parameter = 0.6543)].

Enzyme Kinetics A coupled assay was used for kinetic analysis. 917 nM of Arabidopsis thaliana 4CL1 (NCBI accession version NP_175579.1) in 50 mM Tris-HCl, pH 8.0, 5 mM MgCl2, 2 mM ATP, 2 mM p-coumaric acid, and 3 mM coenzyme A was allowed to equilibrate for 24 hours to generate p-coumaroyl CoA at ~ 2 mM final concentration. 75 µL of this mastermix was aliquoted into Eppendorf tubes, and the assay is initiated by addition of 5 µL of substrate followed by 20 µL of enzyme. For shikimate kinetics, 21.22 nM of wild-type CbHCT, and 64 µM of R356A, R356D, and R356E were assayed against 10, 50, 100, 250, 500, 1000, 2500, and 5000 µM of shikimate. The wild-type HCT reaction was timed for 5 minutes, and the mutant reactions for 15 minutes. For 3,4-dihydroxybenzylamine kinetics, 4.24 µM of wild-type CbHCT, 8.5 µM of R356A, 1.49 µM of R356D, and 4.25 µM of R356E were assayed against 1, 2.5, 5, 10, 25, 50, 75, and 100 mM of 3,4-dihydroxybenzylamine for 5 minutes. For dopamine kinetics, 21.2 nM of wild-type and mutant CbHCT enzymes were assayed against 1, 2.5, 5, 10, 25, 50, 75, and 100 mM of dopamine for 15 minutes. Absolute quantification of initial rates was achieved by normalizing with a standard curve, obtained by running reactions with small amounts of substrate to completion. All velocities measured were in initial rate conditions. All reactions were quenched by addition of 10 µL of 10 M acetic acid. The assays were centrifuged, and analyzed directly by liquid chromatography-mass spectrometry (LC-MS). Detailed procedures of the LC-MS analysis are provided in the Supplementary Experimental Procedures. Km and Vmax

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were determined by fitting raw data to the Michaelis-Menten equation using nonlinear regression in Prism, version 6.0f (GraphPad Software).

Molecular Dynamics MD simulation systems were constructed by solvating the protein (or protein-substrate complex) in a water box with at least 12.5 Å water padding on each side. Following neutralization, a concentration of 0.15 M NaCl was added using the autoionize plugin of VMD45. All simulations were performed using NAMD 2.1046 with the CHARMM36 and CHARMM General force field47-50. For each system, three or five replicas of 100-ns production runs were performed (see Table S2). For more details on the MD simulation and analysis protocols, please see the Supplementary Experimental Procedures.

RESULTS Structural features and catalytic mechanism of Arabidopsis thaliana HCT To shed light on the structural basis for substrate recognition and the catalytic mechanism of HCT, we determined several crystal structures of Arabidopsis thaliana HCT (AtHCT) in its apo, p-coumaroyl CoA-bound, and p-coumaroylshikimate-bound forms (Supplementary Table S1). Similar to several previously reported crystal structures of BAHD acyltransferases38, 51, 52, AtHCT consists of two quasi-symmetric N-terminal (residues 1-171, 374-394) and C-terminal (residues 223-373, 395-431) domains, connected by a long loop (residues 172 to 222) (Figure 1A). Each of the N- and C-terminal domains features a β-sheet core flanked by α-helices with similar spatial arrangement, suggesting the BAHD acyltransferase fold might have evolved from

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an ancient domain duplication event, although no significant sequence similarity could be detected between the amino acid sequences of the two domains. The active site is situated at the interface of the domains. Close examination of the p-coumaroylshikimate-bound AtHCT structure reveals several structural features underlying the catalytic mechanism of HCT (Figure 1A, B)38, 52. For example, the τ-nitrogen of the universally conserved catalytic His153, provided by the N-terminal domain, forms a hydrogen bond with the shikimate 5-oxygen of p-coumaroylshikimate. This configuration is consistent with the role of His153 as a general base that deprotonates the 5hydroxyl of the acyl acceptor substrate shikimate, priming it for nucleophilic attack on the carbonyl carbon of the acyl donor p-coumaroyl CoA. Furthermore, the indolic nitrogen of Trp371 from the C-terminal domain is within hydrogen bonding distance of the carbonyl oxygen of p-coumaroyl CoA, consistent with its proposed role as an oxyanion hole that stabilizes the negative charge on the tetrahedral intermediate formed after the nucleophilic attack. In the final step of the catalytic cycle, coenzyme A is released from the tetrahedral intermediate as a leaving group to produce the ester product p-coumaroylshikimate. Additional residues in AtHCT that contribute to p-coumaroylshikimate recognition include Thr369 and Arg356, forming a hydrogen bond with the 3-hydroxyl and a salt bridge with the carboxyl of the shikimate moiety, respectively.

Distinct active site conformational states in HCTs When comparing the apo, p-coumaroyl CoA-bound, and p-coumaroylshikimate-bound AtHCT structures, we noticed several distinct active site conformational changes between apo and holo AtHCT structures (Figure 2). Consistent conformational changes in the same active site

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regions were also observed in a comparison of the previously reported apo and pcoumaroylshikimate and CoA-bound ternary Sorghum bicolor HCT (SbHCT) structures38 (Figure 2). For ease of reference, all residues are numbered according to their relative position in the AtHCT sequence hereafter. For example, there is a switch-like conformational shift in the catalytic His153. In structures where p-coumaroylshikimate is present, the imidazole side chain of His153 is stabilized in a 180° rotation relative to its apo conformation, a position that facilitates hydrogen bond formation with the shikimate 5-oxygen. Interestingly, in the p-coumaroyl CoA-bound AtHCT structure, His153 adopts an intermediate conformation with a side chain rotation of about 90° relative to its apo state (Figure 2A). Furthermore, in the presence of p-coumaroylshikimate, the side chain of Arg356 is stabilized in a conformation inside of the active site, compared to its exterior position in the apo structure. This transition is likely mediated by electrostatic attraction between the positively charged guanidinium group of the arginine side chain and the negatively charged carboxyl group of shikimate, and facilitated by the flexibility of the surrounding peptide backbone (Figure 2A-B). In addition, we observed that three loops surrounding the active site, namely L1 (residues 31-34), L2 (residues 357-365), and L3 (residues 392-398), shift inward upon binding of various ligands, resulting in shrinkage of the HCT active site (Figure 2B). A volume calculation of the acyl acceptor binding pocket (referred to as active site volume hereafter) reveals 28% and 53% shrinkage in two AtHCT holo structures in complex with pcoumaroyl CoA and p-coumaroylshikimate respectively, relative to the AtHCT apo structure, and 39% shrinkage in the SbHCT ternary structure in complex with p-coumaroylshikimate and CoA, relative to the SbHCT apo structure (Table 1)40. Altogether, these observations highlight

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the dynamic nature of HCT active site, and implicate the functional importance of specific conformational changes in catalysis. MD simulations of AtHCT structures corroborate our observations from comparative structural analysis. Five replicas of 100-ns simulations, initiated from the corresponding crystal structures, were performed for AtHCT in the apo state as well as in complex with p-coumaroyl CoA and shikimate (Supplementary Table S2). All simulations revealed considerable fluctuations in protein side chains and active site loops, which was reflected in the high variability of the active site volume. For this reason, analysis of structural elements directly involved in catalysis, such as Arg356 and His153, yielded more valuable information. The overall trend of the simulated dynamics underlying these residues is consistent with that derived from our structural analysis. For instance, compared with simulations of apo AtHCT, where a broad conformational distribution of Arg356 is observed, simulations of p-coumaroyl CoA and shikimate-bound AtHCT reveal that this residue is stabilized within an optimal distance of the native substrate (Figure 2C). A similar trend is observed for His153 (Supplementary Figure S2). Additionally, clustering analysis reveals that once AtHCT is bound to its substrates, Arg356 adopts a predominantly internal conformation (Figure 2D). In contrast, the apo simulations are dominated by external conformations, including one in which the residue is oriented opposite to the active site (Figure 2E, Supplementary Figure S3). The much larger conformational space sampled by Arg356 in the latter simulations reflects its considerable flexibility in the apo state, whereas simulations of the ternary complex indicate that binding native substrates has the effect of stabilizing this key active site residue in the preferred conformation. Notably, the apo simulations also reveal Arg356 conformations resembling the internal state (Supplementary

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Figure S3), suggesting that the swinging motion of this residue constitutes a rapid conformational shift that can be utilized by the enzyme to facilitate its native reaction.

An arginine handle dictates acyl acceptor specificity in HCT As an indispensible enzyme in plant phenylpropanoid metabolism, HCT is conserved across all extant land plants13. To infer the evolutionary history and conserved sequence features of HCTs, we performed multiple sequence alignment (MSA) and phylogenetic analysis using 35 HCT ortholog sequences collected from various sequence databases, representing all major land plant lineages (Figure 2F, Supplementary Figure S1, and Supplementary Data S1). The MSA reveals universal conservation of Arg356 as well as a high degree of conservation of the surrounding residues (354-362), indicating that Arg356 is likely essential for the catalytic function of HCT and the particular combination of its neighboring residues as part of L2 may confer its structural flexibility (Figure 2F). Other universally conserved residues among HCTs include Thr369 and Trp371, both of which play important roles throughout the catalytic cycle of HCT (Figure 1B and 2F). Interestingly, Coleus blumei RAS (CbRAS), a neofunctionalized enzyme derived from HCT24,

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, retains neither Arg356 nor Thr369 (Figure 2F). These

substitutions likely reflect the shift in RAS specificity toward a new acyl acceptor. The presence of a specific and highly conserved electrostatic interaction between the structurally flexible Arg356 and shikimate led us to hypothesize that Arg356 may act as a catalytic “handle” that affixes to shikimate by its carboxyl and orients the shikimate 5-hydroxyl toward the catalytic center via a specific arginine swing-in movement during catalysis. Several conformational states of the Arg356 handle were indeed captured by various HCT structures as well as MD simulations (Figure 2). Based on this hypothesis, we also postulated that it might be

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possible to strategically engineer HCT to favor certain positively charged acyl acceptor substrates if the arginine handle is substituted with a negatively charged residue. To test this hypothesis, we carried out a series of mutagenesis experiments targeting Arg356 followed by enzyme kinetic assays. CbHCT was chosen for these experiments because it was the most soluble and highly expressed enzyme among several HCT orthologs we produced recombinantly in E. coli. Wild-type CbHCT and its R356D, R356E, and R356A mutants (corresponding to residue 350 in the CbHCT sequence) were produced and purified for biochemical assays. Notably, introducing these mutations to CbHCT did not appear to alter the production, solubility, and stability of the recombinant protein when expressed in E. coli (Supplementary Figure S4). Pseudo-first-order kinetic assays of wild-type CbHCT against shikimate reveal a Km of 388 µM and a kcat of 30.1 s-1, consistent with previously published kinetic parameters on the same enzyme24. The catalytic activity toward shikimate was entirely abolished in the R356D, R356E and R356A mutants, demonstrating that Arg356 plays an essential role in the native reaction catalyzed by HCT (Figure 3A and Table 2). We posited that the role of Arg356 is twofold. First, the electrostatic attraction between the positively charged Arg356 side chain and negatively charged shikimate molecule facilitates binding of the acyl acceptor substrate into the active site. Second, the nature of the attraction between Arg356 and shikimate is geometrically unique, and thus orients the substrate’s functional groups properly relative to the enzyme’s catalytic machinery, thereby facilitating efficient catalysis. We then investigated the role of Arg356 in catalytic efficiency via MD simulations of wild-type CbHCT and the CbHCT R356E mutant, both in complex with p-coumaroyl CoA and shikimate (Supplementary Table S2). In simulations of wild-type CbHCT, Arg356 is found to anchor shikimate in orientations that

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facilitate nucleophilic attack by its 3-hydroxyl onto p-coumaroyl CoA (Figure 4A). By contrast, in the R356E mutant simulations, shikimate quickly lost such preferred orientations and explored a diversity of positions in the active site (Figure 4B). In all three 100-ns simulations of the R356E mutant, shikimate left the active site toward the end of the trajectories. Next, we characterized the kinetics of each CbHCT mutant toward non-native acyl acceptor substrates. We chose non-native acyl acceptors that resemble shikimate but contain a positively charged amine group in place of the carboxylic acid moiety. Commercial availability limited our substrate selection to 3,4-dihydroxybenzylamine and dopamine, which contain an aromatic ring instead of the non-aromatic six-membered ring as in shikimate (Figure 3B-C). Our hypothesis predicts that R356D and R356E mutants should attract the positively charged nonnative substrates 3,4-dihydroxybenzylamine and dopamine, while wild-type CbHCT should repel these substrates. As R356A is unable to engage any charge-based interaction, it may be expected to display an intermediate catalytic activity. The kinetics of the three CbHCT mutants challenged with 3,4-dihydroxybenzylamine revealed precisely this pattern (Figure 3B and Table 2). Whereas the mutant enzymes are incapable of catalyzing the native HCT reaction, their catalytic performance in utilizing 3,4-dihydroxybenzylamine surpasses that of wild-type CbHCT. R356D is nearly an order of magnitude more efficient than wild-type CbHCT in terms of kcat/Km. Notably, this is primarily due to a significantly lower Km in R356D compared to wild-type CbHCT. R356E has a compromised catalytic rate, but demonstrates an improvement in Km to the extent that it remains five-fold more efficient than wild-type CbHCT. Dopamine is less sterically similar to shikimate than 3,4-dihydroxybenzylamine is, and this property is reflected in the generally unfavorable kinetic parameters measured for this substrate. Neither Vmax nor Km could be determined for wild-type CbHCT toward this acyl acceptor, as the reaction velocity increased

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linearly even at 100 mM substrate. Nevertheless, the CbHCT mutants outperformed the wildtype enzyme in catalyzing this non-native reaction (Figure 3C and Table 2). The differences in magnitude for catalytic efficiency (kcat/Km) among the three mutants are less pronounced for dopamine than for 3,4-dihydroxybenzylamine, but R356D and R356E are slightly more efficient than R356A. Consistent with the 3,4-dihydroxybenzylamine results, this improvement in catalytic efficiency is contributed entirely from Km, as R356D and R356E indeed display lower kcat toward dopamine compared to R356A.

A neutral non-native substrate does not induce conformational change in HCT active site Our kinetic experiments and MD simulations informed us of the necessity of the Arg356 handle in the native reaction catalyzed by HCT involving shikimate, and the sufficiency of the handle’s charge identity to dictate substrate specificity toward charged acyl acceptor molecules. Because electrostatic interactions appear to have a large role in substrate recognition in HCT, we sought to characterize the nature of the interaction between HCT and neutral non-native substrates. We chose 3-hydroxyacetophenone, as it resembles shikimate but lacks an ionizable functional group (Figure 5A). Moreover, we identified 3-hydroxyacetophenone as an HCT substrate in a preliminary screen designed to reveal HCT-mediated catalysis of non-native acyl acceptors (Supplementary Figure S5). Notably, the same assay also identified the previously reported 2,3-dihydroxybenzoic acid as a non-native acyl acceptor (Supplementary Figure S5)24. However, all of the CbHCT variants displayed such low activity toward 3-hydroxyacetophenone that kinetic characterization was infeasible. To shed light on the molecular basis underlying HCT-mediated catalysis of a neutral nonnative substrate, we obtained crystal structures of wild-type CbHCT in apo form, as well as the

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ternary complex with p-coumaroyl CoA and 3-hydroxyacetophenone – though in the latter, electron density supporting p-coumaroyl CoA is scarce. The ternary structure reveals that 3hydroxyacetophenone is bound in a hydrophobic pocket of the enzyme active site (Figure 5A). An overlay of this structure with the p-coumaroylshikimate-bound AtHCT structure further reveals that 3-hydroxyacetophenone is shifted significantly away from the catalytic center relative to the shikimate moiety of p-coumaroylshikimate (Figure 5B). Furthermore, 3hydroxyacetophenone adopts a nonproductive orientation, in which its 3-hydroxyl points away from the catalytic center. The combination of these binding features cause the catalytic group of 3-hydroxyacetophenone to be 7.5 Å away from the carbonyl carbon of p-coumaroyl CoA, and 8.1 Å away from the τ-nitrogen of the catalytic histidine, too far to elicit efficient catalysis (Figure 5B). In the ternary structure, electron density supports two conformations of the catalytic histidine, similar to that of the p-coumaroyl CoA-bound AtHCT structure (Supplementary Figure S6). However, no other significant conformational changes are induced. The conformations of Arg356 and the active site loops resemble those of the apo HCTs more closely than those of the p-coumaroyl CoA or p-coumaroylshikimate-bound HCTs. Consequently, there is little active site shrinkage upon 3-hydroxyacetophenone binding (Figure 5C, Table 1). To further assess the mode of interaction between CbHCT and 3-hydroxyacetophenone, we performed five 100-ns MD simulations of CbHCT in complex with p-coumaroyl CoA and 3hydroxyacetophenone. Five simulations for apo CbHCT as well as p-coumaroyl CoA and shikimate-bound CbHCT were also carried out as controls (Supplemenal Table S2). Similar to apo AtHCT, Arg356 in apo CbHCT adopts both external and internal conformations, with the former dominating the distribution (Supplementary Figure S7). Overall, active site dynamics in simulations of apo versus p-coumaroyl CoA and shikimate-bound CbHCT are consistent with

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those observed in AtHCT (Supplementary Figure S7, Figure 5D-E). For instance, in the presence of shikimate, Arg356 predominantly adopts the internal conformation. In contrast, due to an inability to form a stable salt bridge with Arg356, 3-hydroxyacetophenone explores many conformations inside the active site and is unable to sustain the preferred orientation (Figure 4C). To comprehend whether the loss in productive binding is due to 3-hydroxyacetophenone’s aromaticity, its absence of and 4- and 5- hydroxyls, or its absence of the carboxylic acid moiety, we performed three 100-ns simulations of wild-type CbHCT in complex with two shikimate “mutants”. Whereas the mutant lacking the 4- and 5- hydroxyl groups sustains a similar location and orientation to shikimate, the mutant lacking the carboxyl group explores many conformations inside the active site, reflecting the necessary role of the shikimate carboxyl in facilitating productive binding of the native substrate (Supplementary Figure S8). Simulations of 3-hydroxyacetophenone-bound CbHCT reveal that Arg356 primarily adopts the external conformation, consistent with the apo and 3-hydroxyacetophenone-bound CbHCT crystal structures (Figure 5F). Furthermore, compared with shikimate-bound simulations, where Arg356 is more likely to be located close to the substrate, the 3-hydroxyacetophenone-bound CbHCT simulations resemble apo-CbHCT simulations more closely due to the broader conformational distribution of this residue (Figure 5D). Altogether, these results demonstrate that a neutral nonnative substrate is unable to induce active site conformational changes associated with catalysis.

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DISCUSSION Distinct dynamic conformational states are prevalent throughout HCT substrate binding and catalysis. Though the conformational differences described here are comparatively small in magnitude, they play exquisite roles in various steps within the HCT catalytic cycle. For example, the flipping motion of the imidazole ring of catalytic His153 places the imidazole τnitrogen 1 Å closer to the 5-hydroxyl of the acyl acceptor substrate shikimate, establishing the proximity necessary to trigger the general base-mediated catalysis. Additionally, the active site surrounding loops, which display root-mean-square deviations (RMSDs) between 1.1 Å and 3.2 Å transitioning from the apo to various native substrate and product-bound states in both AtHCT and SbHCT structures, collectively result in substantial active site shrinkage. Finally, the Arg356 handle undergoes a swing-in movement upon shikimate binding that corresponds to a shift of 1.7 Å in the alpha carbon and 3.5 Å in the guanidinium group. Consequently, a neutral ligand that is unable to induce these active site conformational changes is a poor substrate. Our results suggest that the specific ionic interaction between the Arg356 handle and shikimate is a key structural feature that allows HCT to distinguish between native and nonnative acyl acceptor substrates. The Arg356 handle contributes to multiple facets of HCT’s catalytic mechanism. First, salt bridge formation between the arginine side chain and shikimate carboxyl confers acyl acceptor substrate binding affinity. Further, the specific movement of the Arg356 handle orients shikimate in a catalytically productive conformation in HCT’s rather large active site, thereby facilitating efficient catalysis by increasing the fraction of productive encounters that occur between the enzyme and substrate54. MD simulations exploring interaction of wild-type CbHCT with a shikimate “mutant” lacking the carboxyl group further corroborate

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the necessary role of the ionic interaction between Arg356 and the native substrate in catalytically productive binding. The Arg356 handle is an apparently important specificity feature – present in HCT and the closely related BAHD acyltransferase hydroxycinnamoyl CoA: quinate hydroxycinnamoyl transferase (HQT), which catalyzes a reaction with quinate, an acyl acceptor that strongly resembles shikimate – but not conserved in the closely related RAS, which utilizes a structurally different acyl acceptor. It is difficult to assess whether more distant BAHD homologs that catalyze reactions with positively charged acyl acceptors use a negatively charged handle as part of the catalytic mechanism, as low sequence identity and divergent active site architecture makes it difficult to predict enzyme-ligand interactions. While mutating Arg356 resulted in a total loss of HCT’s native enzymatic activity, mutating Arg356 to negatively charged residues actually increased specificity toward certain positively charged non-native substrates, illustrating that Arg356 is both necessary and sufficient to confer HCT substrate selectivity on the level of electrostatic identity. Interestingly, our kinetic analysis revealed that R356A is unable to utilize shikimate, but accepts 3,4-dihydroxybenzylamine and dopamine as substrates. A possible explanation is that the greater hydrophobicity of the aromatic substrates makes them more likely than shikimate to diffuse into areas of the active site that are proximal to the catalytic center, leading to higher turnover in Arg356 mutants. Overall, the observation implies that the Arg356 handle is more essential in the context of shikimate catalysis than it is in the context of nonnative substrate catalysis. HCT is an essential enzyme that directs metabolic flux into a crucial branch of the plant phenylpropanoid pathway. But unlike some other essential metabolic enzymes, such as acetylcholinesterase or superoxide dismutase, which are characterized as diffusion-limited and

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evolutionarily perfected enzymes55, 56, HCT has a few-hundred micromolar Km, and exists in a cellular environment containing many endogenous plant metabolites with suitable functional groups to qualify as competing substrates. As an enzyme with non-ideal catalytic efficiency and low substrate specificity, how does HCT maintain specificity in vivo in order to maintain flux into the important downstream phenylpropanoid pathway? An important consideration is that improved catalytic efficiency of an enzyme in isolation does not necessarily translate to improved organismal fitness. For example, if a metabolite is a common precursor for multiple metabolic pathways, each of the enzymes utilizing this metabolite would have to evolve toward optimal catalytic efficiency in order to collectively achieve balanced metabolic fluxes into the downstream pathways. The acyl acceptor substrate of HCT, shikimate, is a common precursor of aromatic amino acid biosynthesis. As many characterized BAHD acyltransferases exhibit Km values lower than that of HCT, it may be that the seemingly low substrate binding affinity of HCT toward shikimate has evolved to be in concordance with the concentration of this metabolite in the cell, establishing a control mechanism wherein metabolic flux through HCT into the downstream phenylpropanoid pathway is sensitive to the availability of cytosolic shikimate19. For instance, HCT can act as a shikimate “sensor” by operating at a low turnover rate in conditions where shikimate is present in limiting concentrations, thereby limiting flux into the phenylpropanoid pathway19. This suggests that HCT’s kinetic parameters have evolved under systems-level constraints, reflecting the optimization of flux into different branches of organismal metabolism22, 57. HCT’s other challenge is avoiding competitive inhibition in vivo. At first glance, it may seem that any endogenous metabolite containing hydroxyl or amine functional groups can be a potential substrate, readily entering HCT’s rather large active site and competing with shikimate

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for catalysis. However, our structural and functional analyses shed light on the molecular strategies that HCT employs to maintain specificity toward shikimate over other non-native substrates. For instance, Thr369, which forms a stabilizing hydrogen bond with the shikimate 3hydroxyl group, is adapted to accommodate the native substrate’s unique non-aromatic 6membered ring geometry. This suggests that aromatic compounds with planar aromatic ring hydroxyls are worse substrates because they cannot simultaneously engage Thr369 and the τnitrogen of the catalytic His153. Accordingly, an effective substrate should be able to engage these active site elements in a way that stabilizes catalytically productive conformations of HCT. Although dynamic exchange between conformational states is crucial to substrate binding and catalysis in HCT, recent literature suggests that too much conformational freedom can be detrimental to both native and non-native functions. For instance, a study of negative epistasis in TEM-1 β lactamase suggests that increased structural flexibility can lead to a greater conformational diversity, potentially dominated by states that are counterproductive to substrate binding and/or catalysis58. Additionally, a study of intermediates in the laboratory evolution of a phosphotriesterase to an arylesterase suggests that the emergence of new, productive catalytic states can occur via stabilization of pre-existing, though perhaps minor, conformational states59. Altogether, these findings suggest that the coordination of conformational ensembles is a highly complex and specialized event unique to each enzyme, and that the impact of conformational diversity on the evolution of new functions must be weighed in the context of an enzyme’s catalytic cycle. Pre-existing, catalytically competent states in an enzyme’s conformational ensemble can be stabilized by non-native ligands and facilitate neofunctionalization. On the other hand, excessive dynamic freedom may translate into the prevalence of an unproductive ensemble of conformational states. Our structural and molecular dynamic observations indicate

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that non-native catalysis in HCT may not always proceed through the same catalytically productive conformation as shikimate catalysis, and is marked by excessive conformational freedom. This implies that such catalytic modes are feasible and inefficient because they leverage HCT’s dynamic conformational diversity. Interestingly, our analysis of MD simulation trajectories reveals that a subset of the apo AtHCT and CbHCT populations exhibit dynamic states resembling catalysis, featuring Arg356 in the internal conformation (Figure 2C and 5D). This result is in accordance with a previous study showing that dynamic states relevant to catalysis are present in the intrinsic dynamics of the prolyl cis-trans isomerase cyclophilin A in its substrate-free state60. HCT’s native substrate, shikimate, is catalyzed efficiently because it can leverage the specificity of electrostatic interactions and hydrogen bonds to achieve favorable orientation in the active site while simultaneously shifting the population equilibrium of enzyme molecules into the catalytic state. On the other hand, a plethora of compounds lacking these features will be catalyzed much less efficiently, as they must enter the active site in a proper conformation with little guidance from key surrounding residues at a time when the enzyme is in a catalytically-favorable substate. In summary, our study comprises the first in-depth investigation of the molecular mechanisms dictating native versus non-native catalysis in the substrate-permissive BAHD acyltransferases. As enzyme promiscuity is a framework for the evolution of new enzymatic functions, it is likely that the extensive divergence of the BAHD acyltransferase family throughout land plants was facilitated by the substrate flexibility of an ancestral enzyme or enzymes. Furthermore, as evidenced in the case of RAS neofunctionalization from its progenitor enzyme, HCT’s messy biochemistry provides a starting point for the evolution of new enzymatic activities24, 26. In general, the complex dynamic interplay between enzymes and their substrates,

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and the mutations that perturb these intricate networks, are vital mechanisms leveraged by nature to give rise to new enzymatic functions and subsequently increase metabolic diversity61, 62.

AUTHOR CONTRIBUTION O.L. and J.K.W. designed the research; O.L., J.P.N., J.K.W. collected X-ray diffraction data and solved crystal structures. Y.C.C., C.F.T., and Y.W. performed MD simulations. O.L. performed mutagenesis and kinetic assays. O.L., Y.C.C., Y.W., and J.K.W. interpreted the results and wrote the paper.

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ACKNOWLEDGMENTS We thank John Ralph for providing p-coumaroylshikimate.

FUNDING The X-ray crystallography was partly conducted at beamlines 8.2.1 and 8.2.2 at Advanced Light Source supported by Howard Hughes Medical Institute, and partly conducted at the Northeastern Collaborative Access Team (NE-CAT) beamlines, which are funded by the National Institute of General Medical Sciences from the National Institutes of Health (P41 GM103403). The Pilatus 6M detector on NE-CAT 24-ID-C beam line is funded by a NIH-ORIP HEI grant (S10 RR029205). This research used resources of the Advanced Photon Source, a U.S. Department of Energy (DOE) Office of Science User Facility operated for the DOE Office of Science by Argonne National Laboratory under Contract No. DE-AC02-06CH11357. This work used the Extreme Science and Engineering Discovery Environment (XSEDE), which is supported by National Science Foundation grant number ACI-1053575. J.P.N. is an investigator with the Howard Hughes Medical Institute. This work was supported by the Project 409813 from University Grants Committee of Hong Kong (Y.W.), the Pew Scholar Program in the Biomedical Sciences (J.K.W.), and the Searle Scholars Program (J.K.W.).

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SUPPORTING INFORMATION Supplementary Experimental Procedures Supplementary References Supplementary Figure S1: Maximum likelihood tree inferring the phylogenetic relationship between 35 HCT and 2 RAS sequences. Supplementary Figure S2: Distribution of the distance change (∆d) between His153 and pcoumaroylshikimate in apo- and p-coumaroyl CoA and shikimate-bound AtHCT simulations. Supplementary Figure S3: Clusters of Arg356 sampled in apo-AtHCT simulations. Supplementary Figure S4: SDS-PAGE gel of wild-type, R350A, R350D, and R350E CbHCT. Supplementary Figure S5: Orbitrap LC-MS data detecting p-coumaroyl-2,3-dihydroxybenzoic acid and p-coumaroyl-3-hydroxyacetophenone as non-native substrates for HCT. Supplementary Figure S6: Active site of p-coumaroyl CoA and 3-hydroxyacetophenone-bound CbHCT. Supplementary Figure S7: Clusters of Arg356 from clustering analysis of apo CbHCT simulations. Supplementary Figure S8: 2D scatter plots of shikimate “mutant” position and orientation in CbHCT simulations. Supplementary Figure S9: Vectors used to compute the orientation of shikimate and 3hydroxyacetophenone. Supplementary Table S1: Refinement statistics for X-ray crystallography structures. Supplementary Table S2: List of MD simulations performed in this study. Supplementary Data S1: Extended multiple sequence alignment of HCT orthologs. Supplementary Data S2: Codon optimized sequence of CbHCT for recombinant protein expression in E. coli.

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[29] Winn, M. D., Ballard, C. C., Cowtan, K. D., Dodson, E. J., Emsley, P., Evans, P. R., Keegan, R. M., Krissinel, E. B., Leslie, A. G. W., McCoy, A., McNicholas, S. J., Murshudov, G. N., Pannu, N. S., Potterton, E. A., Powell, H. R., Read, R. J., Vagin, A., and Wilson, K. S. (2011) Overview of the CCP4 suite and current developments, Acta Crystallogr D 67, 235-242. [30] Evans, P. (2006) Scaling and assessment of data quality, Acta Crystallogr D 62, 72-82. [31] Adams, P. D., Afonine, P. V., Bunkoczi, G., Chen, V. B., Davis, I. W., Echols, N., Headd, J. J., Hung, L. W., Kapral, G. J., Grosse-Kunstleve, R. W., McCoy, A. J., Moriarty, N. W., Oeffner, R., Read, R. J., Richardson, D. C., Richardson, J. S., Terwilliger, T. C., and Zwart, P. H. (2010) PHENIX: a comprehensive Python-based system for macromolecular structure solution, Acta Crystallogr D 66, 213-221. [32] Emsley, P., and Cowtan, K. (2004) Coot: model-building tools for molecular graphics, Acta Crystallogr D 60, 2126-2132. [33] Agarwala, R., Barrett, T., Beck, J., Benson, D. A., Bollin, C., Bolton, E., Bourexis, D., Brister, J. R., Bryant, S. H., Lanese, K., Charowhas, C., Clark, K., DiCuccio, M., Dondoshansky, I., Federhen, S., Feolo, M., Funk, K., Geer, L. Y., Gorelenkov, V., Hoeppner, M., Holmes, B., Johnson, M., Khotomlianski, V., Kimchi, A., Kimelman, M., Kitts, P., Klimke, W., Krasnov, S., Kuznetsov, A., Landrum, M. J., Landsman, D., Lee, J. M., Lipman, D. J., Lu, Z. Y., Madden, T. L., Madcj, T., Marchler-Bauer, A., KarschMizrachi, I., Murphy, T., Orris, R., Ostell, J., O'Sullivan, C., Panchenko, A., Phan, L., Preuss, D., Pruitt, K. D., Rodarmer, K., Rubinstein, W., Sayers, E. W., Schneider, V., Schuler, G. D., Sherry, S. T., Sirotkin, K., Siyan, K., Slotta, D., Soboleva, A., Soussov, V., Starchenko, G., Tatusova, T. A., Todorov, K., Trawick, B. W., Vakatov, D., Wang, Y. L., Ward, M., Wilbur, W. J., Yaschenko, E., Zbicz, K., and Coordinators, N. R. (2016) Database resources of the National Center for Biotechnology Information, Nucleic Acids Res 44, D7-D19. [34] Sundell, D., Mannapperuma, C., Netotea, S., Delhomme, N., Lin, Y. C., Sjodin, A., Van de Peer, Y., Jansson, S., Hvidsten, T. R., and Street, N. R. (2015) The Plant Genome Integrative Explorer Resource: PlantGenIE.org, New Phytol 208, 1149-1156. [35] Matasci, N., Hung, L. H., Yan, Z. X., Carpenter, E. J., Wickett, N. J., Mirarab, S., Nguyen, N., Warnow, T., Ayyampalayam, S., Barker, M., Burleigh, J. G., Gitzendanner, M. A., Wafula, E., Der, J. P., dePamphilis, C. W., Roure, B., Philippe, H., Ruhfel, B. R., Miles, N. W., Graham, S. W., Mathews, S., Surek, B., Melkonian, M., Soltis, D. E., Soltis, P. S., Rothfels, C., Pokorny, L., Shaw, J. A., DeGironimo, L., Stevenson, D. W., Villarreal, J. C., Chen, T., Kutchan, T. M., Rolf, M., Baucom, R. S., Deyholos, M. K., Samudrala, R., Tian, Z. J., Wu, X. L., Sun, X., Zhang, Y., Wang, J., Leebens-Mack, J., and Wong, G. K. S. (2014) Data access for the 1,000 Plants (1KP) project, Gigascience 3. [36] Notredame, C., Higgins, D. G., and Heringa, J. (2000) T-Coffee: A novel method for fast and accurate multiple sequence alignment, J Mol Biol 302, 205-217. [37] Robert, X., and Gouet, P. (2014) Deciphering key features in protein structures with the new ENDscript server, Nucleic Acids Res 42, W320-W324. [38] Walker, A. M., Hayes, R. P., Youn, B., Vermerris, W., Sattler, S. E., and Kang, C. (2013) Elucidation of the structure and reaction mechanism of sorghum hydroxycinnamoyltransferase and its structural relationship to other coenzyme adependent transferases and synthases, Plant Physiol 162, 640-651.

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[39] Krissinel, E., and Henrick, K. (2004) Secondary-structure matching (SSM), a new tool for fast protein structure alignment in three dimensions, Acta Crystallogr D 60, 2256-2268. [40] Oliveira, S. H., Ferraz, F. A., Honorato, R. V., Xavier-Neto, J., Sobreira, T. J., and de Oliveira, P. S. (2014) KVFinder: steered identification of protein cavities as a PyMOL plugin, BMC Bioinformatics 15, 197. [41] Delano, W. L. (2002) The PyMOL Molecular Graphics System. [42] Kumar, S., Stecher, G., and Tamura, K. (2016) MEGA7: Molecular Evolutionary Genetics Analysis version 7.0 for bigger datasets, Mol Biol Evol. [43] Edgar, R. C. (2004) MUSCLE: multiple sequence alignment with high accuracy and high throughput, Nucleic Acids Res 32, 1792-1797. [44] Le, S. Q., and Gascuel, O. (2008) An improved general amino acid replacement matrix, Mol Biol Evol 25, 1307-1320. [45] Humphrey, W., Dalke, A., and Schulten, K. (1996) VMD: visual molecular dynamics, J Mol Graph 14, 33-38, 27-38. [46] Phillips, J. C., Braun, R., Wang, W., Gumbart, J., Tajkhorshid, E., Villa, E., Chipot, C., Skeel, R. D., Kale, L., and Schulten, K. (2005) Scalable molecular dynamics with NAMD, J Comput Chem 26, 1781-1802. [47] Best, R. B., Zhu, X., Shim, J., Lopes, P. E., Mittal, J., Feig, M., and Mackerell, A. D., Jr. (2012) Optimization of the additive CHARMM all-atom protein force field targeting improved sampling of the backbone phi, psi and side-chain chi(1) and chi(2) dihedral angles, J Chem Theory Comput 8, 3257-3273. [48] Vanommeslaeghe, K., Hatcher, E., Acharya, C., Kundu, S., Zhong, S., Shim, J., Darian, E., Guvench, O., Lopes, P., Vorobyov, I., and MacKerell, A. D. (2010) CHARMM General Force Field: A Force Field for Drug-Like Molecules Compatible with the CHARMM All-Atom Additive Biological Force Fields, Journal of Computational Chemistry 31, 671-690. [49] Yu, W. B., He, X. B., Vanommeslaeghe, K., and MacKerell, A. D. (2012) Extension of the CHARMM general force field to sulfonyl-containing compounds and its utility in biomolecular simulations, Journal of Computational Chemistry 33, 2451-2468. [50] Vanommeslaeghe, K., and MacKerell, A. D. (2012) Automation of the CHARMM General Force Field (CGenFF) I: Bond Perception and Atom Typing, J Chem Inf Model 52, 31443154. [51] Ma, X. Y., Koepke, J., Panjikar, S., Fritzsch, G., and Stockigt, J. (2005) Crystal structure of vinorine synthase, the first representative of the BAHD superfamily, Journal of Biological Chemistry 280, 13576-13583. [52] Lallemand, L. A., Zubieta, C., Lee, S. G., Wang, Y. C., Acajjaoui, S., Timmins, J., McSweeney, S., Jez, J. M., McCarthy, J. G., and McCarthy, A. A. (2012) A Structural Basis for the Biosynthesis of the Major Chlorogenic Acids Found in Coffee, Plant Physiology 160, 249-260. [53] Petersen, M., Abdullah, Y., Benner, J., Eberle, D., Gehlen, K., Hucherig, S., Janiak, V., Kim, K. H., Sander, M., Weitzel, C., and Wolters, S. (2009) Evolution of rosmarinic acid biosynthesis, Phytochemistry 70, 1663-1679. [54] Bar-Even, A., Milo, R., Noor, E., and Tawfik, D. S. (2015) The Moderately Efficient Enzyme: Futile Encounters and Enzyme Floppiness, Biochemistry-Us 54, 4969-4977. [55] Quinn, D. M. (1987) Acetylcholinesterase - Enzyme Structure, Reaction Dynamics, and Virtual Transition-States, Chem Rev 87, 955-979.

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[56] Rotilio, G., Bray, R. C., and Fielden, E. M. (1972) A pulse radiolysis study of superoxide dismutase, Biochim Biophys Acta 268, 605-609. [57] Suzuki, H., Nishino, T., and Nakayama, T. (2007) cDNA cloning of a BAHD acyltransferase from soybean (Glycine max): Isoflavone 7-O-glucoside-6"-Omalonyltransferase, Phytochemistry 68, 2035-2042. [58] Dellus-Gur, E., Elias, M., Caselli, E., Prati, F., Salverda, M. L., de Visser, J. A., Fraser, J. S., and Tawfik, D. S. (2015) Negative Epistasis and Evolvability in TEM-1 betaLactamase--The Thin Line between an Enzyme's Conformational Freedom and Disorder, J Mol Biol 427, 2396-2409. [59] Campbell, E., Kaltenbach, M., Correy, G. J., Carr, P. D., Porebski, B. T., Livingstone, E. K., Afriat-Jurnou, L., Buckle, A. M., Weik, M., Hollfelder, F., Tokuriki, N., and Jackson, C. J. (2016) The role of protein dynamics in the evolution of new enzyme function, Nat Chem Biol. [60] Eisenmesser, E. Z., Millet, O., Labeikovsky, W., Korzhnev, D. M., Wolf-Watz, M., Bosco, D. A., Skalicky, J. J., Kay, L. E., and Kern, D. (2005) Intrinsic dynamics of an enzyme underlies catalysis, Nature 438, 117-121. [61] Clarkson, M. W., and Lee, A. L. (2004) Long-range dynamic effects of point mutations propagate through side chains in the serine protease inhibitor eglin c, Biochemistry-Us 43, 12448-12458. [62] Fuentes, E. J., Gilmore, S. A., Mauldin, R. V., and Lee, A. L. (2006) Evaluation of energetic and dynamic coupling networks in a PDZ domain protein, Journal of Molecular Biology 364, 337-351.

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TABLES Table 1. Measurement of acyl acceptor binding site volumes for crystal structures of SbHCT and AtHCT. HCT Ortholog

Ligand

Volume (Å3)

Constriction (%)

Sorghum bicolor

none

908

-

p-coumaroyl CoA + shikimate

554

39.0

none

1030

-

p-coumaroyl CoA

737

28.4

p-coumaroylshikimate

489

52.5

none

1063

-

Arabidopsis thaliana

Coleus blumei

p-coumaroyl CoA + hydroxyacetophenone

3- 1037

0.02

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Table 2. Summary of kinetic parameters for wild-type CbHCT and R356 mutants. wild-type R356A

R356D

R356E

shikimate Km (mM)

0.3882 ± 0.0303

N/A

N/A

N/A

Vmax (nkat mg-1)

639 ± 14

N/A

N/A

N/A

kcat (s-1)

30.1 ± 0.7

N/A

N/A

N/A

kcat/Km (s-1 M-1)

77537 ± 6289

N/A

N/A

N/A

3,4-dihydroxybenzylamine Km (mM)

265.3 ± 36.8

141.7 ± 8.2

36.03 ± 3.45

16.32 ± 4.83

Vmax (nkat mg-1)

485.9 ± 52.2

623.1 ± 23.8

589.2 ± 22.5

142.5 ± 12.7

kcat (s-1)

22.9 ± 2.5

29.3 ± 1.1

27.7 ± 1.1

6.7 ± 0.6

kcat/Km (s-1 M-1)

86.3 ± 13.1

206 ± 11

768.8 ± 41.5

410.5 ± 51.8

dopamine Km (mM)

N/A

162.6 ± 14.7

49.4 ± 3.6

41.6 ± 1.6

Vmax (nkat mg-1)

N/A

58.02 ± 3.60

30.52 ± 0.99

21.42 ± 0.34

kcat (s-1)

N/A

2.73 ± 0.17

1.44 ± 0.05

1.01 ± 0.02

kcat/Km (s-1 M-1)

N/A

16.8 ± 1.5

29.1 ± 1.4

24.3 ± 0.6

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FIGURE LEGENDS Figure 1. Structure and catalytic mechanism of AtHCT. (A) Schematic ribbon diagram of the overall structure of AtHCT in complex with p-coumaroylshikimate. The two quasi-symmetric Nterminal (light blue) and C-terminal (dark blue) domains are linked by a long loop (red). The zoom-in insert shows the active site highlighting residues key to the native catalytic activity of HCT. Hydrogen bond interactions are indicated with dotted lines (yellow). The |2Fo-Fc| omit electron density map of p-coumaroylshikimate is contoured at 0.8 σ (B) The proposed catalytic mechanism of HCT. Figure 2. Distinct active-site conformational states and dynamics of HCT revealed by X-ray crystallography and MD simulations. (A) Active-site residues His153 and Arg356 show distinct and consistent conformational shifts upon binding of various ligands. (B) Conformational states of the three loop regions surrounding the active site in various HCT structures. The impact of these motions is to constrict the active site volume significantly. (C) Distribution of the distance change (∆d) between Arg356 and p-coumaroylshikimate from simulations of apo (black) and pcoumaroyl CoA and shikimate-bound (red) AtHCT. Calculations were performed by first aligning simulation trajectories to the p-coumaroylshikimate-bound AtHCT crystal structure and then measuring the distance change between Arg356 and p-coumaroylshikimate. A zero ∆d indicates that Arg356 is at an identical distance from the ligand as in the crystal structure. Details can be found in the Supplementary Experimental Procedures. (D) Internal conformation demonstrated by the first cluster of Arg356 from clustering analysis of p-coumaroyl CoA and shikimate-bound AtHCT simulations. (E) External conformations demonstrated by the first two clusters of Arg356 from clustering analysis of apo AtHCT simulations. In (D) and (E), pcoumaroylshikimate from the p-coumaroylshikimate-bound AtHCT crystal structure is shown as

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an active site reference. Arg356 from p-coumaroylshikimate-bound and apo- AtHCT crystal structures are shown in black in (D) and (E), respectively. Percentage of populations for each cluster is labeled. (F) Multiple sequence alignment highlighting L1, L2, L3, and the catalytic regions in select HCT orthologs representing five major land plant lineages. Corresponding sequence regions from CbRAS are displayed at the bottom for comparison. The residue numbering is according to AtHCT. Figure 3. Pseudo first-order Michaelis-Menten kinetics of wild-type, R356A, R356D, and R356E CbHCTs against the native acyl acceptor substrate, shikimate (A), and two non-native acyl acceptor substrates, 3,4-dihydroxybenzylamine (B) and dopamine (C). p-coumaroyl-CoA was used as the acyl donor substrate in all assays at constant and excess concentration. Structures of acyl acceptor substrates are shown above the curves. Figure 4. 2D scatter plots of substrate position and orientation in CbHCT simulations. “Distance” measures the distance between the substrates and Arg356 (or Glu356). “Angle” measures the change in substrates’ orientations with reference to their initial structures (details in the Supplementary Experimental Procedures). Characterized simulations include (A) wildtype CbHCT with regard to shikimate, (B) CbHCT R356E with regard to shikimate, and (C) wild-type CbHCT with regard to 3-hydroxyacetophenone. Figure 5. Structural and dynamic features of CbHCT in complex with p-coumaroyl-CoA and 3hydroxyacetophenone. (A) Chemical structure of 3-hydroxyacetophenone (left) and the |2Fo-Fc| omit electron density map of 3-hydroxyacetophenone in the p-coumaroyl-CoA and 3hydroxyacetophenone-bound CbHCT crystal structure contoured at 0.8 σ (right). (B) The conformation of 3-hydroxyacetophenone relative to the catalytic His153 in CbHCT active site.

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The AtHCT-p-coumaroylshikimate structure is overlaid as a comparison. (C) The conformational states of L1, L2, and L3 and Arg356 in various HCT structures. (D) Distribution of the distance change (∆d) between Arg356 and p-coumaroylshikimate from simulations of apo CbHCT (black), CbHCT in complex with p-coumaroyl CoA and shikimate (red), and CbHCT in complex with p-coumaroyl CoA and 3-hydroxyacetophenone (blue). Details can be found in the Supplementary Experimental Procedures. (E, F) The first cluster of Arg356 conformation from clustering analysis of shikimate- (E) and 3-hydroxyacetophenone-bound (F) CbHCT simulations. As an active site reference, p-coumaroylshikimate from the AtHCT crystal structure is shown in (E) and (F), and 3-hydroxyacetophenone from the CbHCT crystal structure is shown in (F). The conformation of Arg356 from the apo CbHCT crystal structure (E) and the 3hydroxyacetophenone-bound CbHCT crystal structure (F) is shown in black.

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FIGURES Figure 1

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Figure 2

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Figure 3

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Figure 4

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Figure 5

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TABLE OF CONTENTS GRAPHIC

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A

Biochemistry

Page 44 of 48 W371

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 B16 17 18 19 20 H153 21 22 23 HN 24 25 R356 26 27 28 29

T369 3.7 Å

2.9 Å

3.0 Å

3.4 Å

p-coumaroylshikimate

3.0 Å

R356 H153

HO

HO

W371 O

CoA-S

HO

N

6

O NH H 2N

NH 2

5 1

O

H153

HN 4

OH 3

2

OH

T369 O H

HO

W371

HN

CoA-S O NH

O

HN OH OH

R356

O

O

H153

T369 O H

ACS Paragon Plus Environment NH

H 2N

NH 2

HN

W371

HN

CoASH O

NH

O OH OH

R356

O NH H 2N

NH 2

O

T369 O H

A Page 45 of 48

BiochemistryC CoA

0.15

AtHCT (apo) AtHCT (shikimate)

p-coumaroylshikimate

-

-

-

-

Probability

1 2 0.1 3 4 5 Arg356 0.05 6 7 p-coumaroylshikimate 8 p-coumaroyl CoA 9 0 His153 10 −5 0 5 ∆d (Å) 11 12 B p-coumaroylshikimate Arg356 D 13 L1 14 L2 77% 15 16 p-coumaroyl CoA 17 18 19 20 21 CoA Arg356 E 37% 22 L3 23 24 18% p-coumaroylshikimate 25 26SbHCT (apo) 27SbHCT (p-coumaroylshikimate + CoA) 28AtHCT (apo) AtHCT (p-coumaroyl CoA) 29AtHCT (p-coumaroylshikimate) 30 L2 L1 catalytic region 31 F 32 ic 356 33 alyt 369 71 Arg ndle Cat s153 Thr Trp3 ha Hi 34 35AtHCT CbHCT 36SbHCT 37PaHCT ACS Paragon Plus Environment 38SmHCT PpHCT 39 40CbRAS

10

15

p-coumaroylshikimate

p-coumaroylshikimate

L3

O

800

HO

Velocity (nkat/mg)

A

OH

Page 46 of 48

HO

600

OH

400

wt

200 0

0

2

4

HO

400

NH 2

HO

300

wt R356A R356D R356E

200 100 0

C

6

[shikimate] (mM)

500

Velocity (nkat/mg)

B

0

50

100

150

[3,4-dihydroxybenzylamine] (mM)

25

Velocity (nkat/mg)

1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30

Biochemistry

HO

20

NH 2

HO

15 10 5

ACS Paragon Plus 0 0

50

wt R356A R356D R356E Environment 100

[dopamine] (mM)

150

B 0.040

Angle (degree)

150

1120 2 90 3 60 4 30 5 0 6 7

0.030 0.020 0.010 0

5

10

15

Distance (Å)

20

0.000

180

0.005

150

Angle (degree)

180

C

R356E CbHCT

Biochemistry (shikimate)

0.004

120

0.003

90

0.002

60

0.001

30

ACS Paragon Plus Environment 0

0

5

10 15 Distance (Å)

20

0.000

180

WT CbHCT (3−hydroxyacetophenone)

150

Angle (degree)

A WT CbHCT Page 47 of (shikimate) 48

0.004

120

0.003

90

0.002

60

0.001

30

0

0.005

0

5

10 15 Distance (Å)

20

0.000

D Biochemistry

A O

OH

CbHCT (apo) Page 48 CbHCT (shikimate) CbHCT (3-hydroxyacetophenone)

of 48

Probability

1 0.08 2 3 3-hydroxyacetophenone 0.06 4B 5 6 0.04 7 p-coumaroyl CoA 8 0.02 9 10 11 0 −5 0 5 10 15 3-hydroxyacetophenone 12 ∆d (Å) 13 p-coumaroylshikimate 7.5 Å 14 15 E Arg356 16 8.1 Å 17 His153 56% 18 Arg356 p-coumaroylshikimate 19 C Handle 20 21 L1 22L2 23 24 25 F Arg356 26 3-hydroxyacetophenone 27 61% 28 29 p-coumaroylshikimate 30 p-coumaroyl CoA L3 31 32 p-coumaroylshikimate 3-hydroxyacetophenone 33 AtHCT (apo) ACS Paragon Plus Environment 34 AtHCT (p-coumaroylshikimate) 35 CbHCT (apo) CbHCT (p-coumaroyl CoA + 3-hydroxyacetophenone) 36